JP6836782B2 - Hose fastening device - Google Patents

Description

The present invention relates to a hose fastening device for crimping and fixing a metal fitting to a hose with a single caulking device at each of a plurality of locations in the longitudinal direction of the hose.

As disclosed in Patent Document 1, when the metal fitting is crimped and fixed to the hose, first, the hose is abutted against the abutting member to perform positioning. After that, the metal fittings are crimped and fixed to the hose. Then, in Patent Document 1, the hose to which the metal fitting is fixed is discharged in the direction opposite to the abutting direction.

Japanese Unexamined Patent Publication No. 2003-285127

By the way, the work of crimping and fixing the metal fittings to the hose is generally performed at a plurality of places of the hose such as both ends of the hose. Therefore, it is inefficient if the hose is discharged every time one metal fitting is grasped. Therefore, it is conceivable to caulk the plurality of metal fittings into the hose in order with one caulking device while moving the hose to which the plurality of metal fittings are attached in one direction.

However, since the hose is usually abutted and positioned as in Patent Document 1, the hose can be moved in the direction opposite to the abutting direction, but the hose is located behind the abutted position. Could not be moved.

The present invention has been made in view of the above circumstances, and an object of the present invention is to move a hose to which a plurality of metal fittings are mounted in one direction, and to sequentially move the plurality of metal fittings with one caulking device. It is to provide a hose fastening device capable of caulking.

The present invention is a hose fastening device for crimping and fixing a metal fitting to the hose at each of a plurality of locations in the longitudinal direction of the hose, and a stage on which the hose to which the plurality of metal fittings are mounted is placed. When a transport device that transports the stage in one direction along the longitudinal direction of the hose, a plurality of detection pieces provided on the stage for each metal fitting, and a crimping portion of the metal fitting are located at a crimping position. A sensor that detects the detection piece, a controller that suspends the stage by controlling the transport device when the sensor detects the detection piece, and a controller that suspends the stage when the stage is paused. the crimping the crimping portion of the metal member at a position that caulking, have a, one and caulking device for fixing the hose to the fitting, the controller conveys the stage by the conveying device in one direction However, each time the sensor detects the detection piece, the stage is temporarily stopped, so that the plurality of metal fittings are sequentially fixed to the hose by the one caulking device .

According to the present invention, a stage on which hoses mounted with a plurality of metal fittings are mounted is conveyed in one direction, and the stage is temporarily stopped each time a sensor detects a detection piece provided for each of the plurality of metal fittings. Let me crimp. By pausing the stage each time the sensor detects a detection piece, the caulking points of the plurality of metal fittings can be sequentially positioned at the caulking positions. Then, each time the stage is paused, a plurality of metal fittings can be fixed to the hose in order by crimping the crimped portion of the metal fitting at the crimping position. As a result, the hose to which the plurality of metal fittings are attached can be moved in one direction, and the plurality of metal fittings can be crimped to the hose in order by one crimping device.

It is a side view of the hose fastening device. It is a side view of a stage. It is a top view of the stage. It is an enlarged view of the main part A of FIG. It is a top view which shows the positional relationship between a stage and a sensor when a caulking part C1 is positioned at a caulking position. It is a top view which shows the positional relationship between a stage and a sensor when a caulking part C2 is positioned at a caulking position. It is a top view which shows the positional relationship between a stage and a sensor when a caulking part C3 is positioned at a caulking position. It is a top view which shows the positional relationship between a stage and a sensor when a caulking part C4 is positioned at a caulking position. It is a flowchart which shows the operation of a hose fastening device. It is a continuation of FIG.

Hereinafter, preferred embodiments of the present invention will be described with reference to the drawings.

(Structure of hose fastening device)
In the hose fastening device according to the embodiment of the present invention, a metal fitting is caulked and fixed to the hose by one caulking device at each of a plurality of locations in the longitudinal direction of the hose. In the present embodiment, there are a total of four locations, one at both ends of one hose formed by connecting two cutting hoses via an intermediate metal fitting, and the other at both ends of the intermediate metal fitting in the longitudinal direction of the hose. Although each is described as caulking, the hose configuration, caulking points, and the number of caulking points are not limited to this.

As shown in FIG. 1 which is a side view, the hose fastening device 1 includes a stage 2, a transport device 3, and a caulking device 4. The hose 31 is placed on the stage 2 with the left-right direction of FIG. 1 as the longitudinal direction. The transport device 3 moves the stage 2 in the left-right direction.

(stage)
As shown in FIG. 2 which is a side view of the stage 2 and FIG. 3 which is a top view of the stage 2, a hose 31 to which a plurality of metal fittings 32 are attached is placed on the stage 2. The hose 31 is placed when the stage 2 is located at the starting position, which is the starting point of the movement. The hose 31 is configured by connecting two cutting hoses 33 via an intermediate metal fitting 34. Metal fittings 32 are attached to both ends of the hose 31. The intermediate metal fitting 34 is a kind of metal fitting 32.

The stage 2 includes a substrate 11, a fixed stage 12, a movable stage 13, and a spring (biasing means) 14.

The substrate 11 is a rectangular plate extending along the longitudinal direction of the hose 31. The substrate 11 is fixed to a movable portion described later of the transfer device 3, and is conveyed by the transfer device 3. A fixed stage 12, a movable stage 13, a spring 14, and the like are provided on the substrate 11.

Three fixed stages 12 are arranged side by side in the central portion of the substrate 11 in the longitudinal direction of the hose 31. Each of the fixed stages 12 is fixed on the substrate 11 and supports a part of the hose 31 to which the metal fitting 32 is attached. In the present embodiment, the fixed stage 12 arranged in the center of the substrate 11 is formed with a recess 12a into which the intermediate metal fitting 34 is fitted. By fitting the intermediate metal fitting 34 into the recess 12a, the intermediate metal fitting 34 is supported by the fixed stage 12, and the intermediate metal fitting 34 is positioned. Further, the other two fixing stages 12 are formed with grooves into which the hose 31 (cutting hose 33) is fitted.

The movable stages 13 are arranged at both ends of the substrate 11 in the longitudinal direction of the hose 31. The movable stage 13 is made movable in the longitudinal direction of the hose 31 by engaging with the rail 15 provided on the substrate 11. The movable stage 13 is provided with a recess 13a into which the metal fitting 32 is fitted. By fitting the metal fitting 32 into the recess 13a, the metal fitting 32 is supported by the movable stage 13 and the metal fitting 32 is positioned.

The springs 14 are provided at both ends of the substrate 11, respectively. The spring 14 is arranged between the fixture 16 fixed to the end of the substrate 11 and the movable stage 13, and the stripper bolt 17 penetrates the inside thereof. The stripper bolt 17 is inserted through a hole provided in the fixture 16 and its tip is screwed into the movable stage 13 to support the movable stage 13 so as to be movable in the longitudinal direction of the hose 31. The spring 14 urges the movable stage 13 in the direction in which the metal fitting 32 is attached to the hose 31. That is, the spring 14 on the left side in the drawing urges the movable stage 13 on the left side in the drawing to the right side, so that the metal fitting 32 attached to the left end of the hose 31 is urged toward the hose 31. Further, the spring 14 on the right side in the drawing urges the movable stage 13 on the right side in the drawing to the left side, so that the metal fitting 32 attached to the right end of the hose 31 is urged toward the hose 31.

In this way, by urging the movable stage 13 with the spring 14 in the direction in which the metal fitting 32 is attached to the hose 31, the state in which the metal fitting 32 is attached to the hose 31 can be maintained. Therefore, the misalignment (insufficient insertion) between the metal fitting 32 and the hose 31 can be suppressed.

Further, the movable stage 13 can move in the direction in which the metal fitting 32 is attached to the hose 31 by being urged by the spring 14, and the metal fitting 32 is attached to the hose 31 against the urging force of the spring 14. It can move in the direction opposite to the mounting direction. Therefore, even if there is a variation in the length of the cutting hose 33, this variation can be absorbed by the movement of the movable stage 13. Further, even if the cutting hose 33 is slightly stretched when the metal fitting 32 is crimped, the movable stage 13 absorbs the stretched allowance by moving in the direction opposite to the direction in which the metal fitting 32 is attached to the hose 31. be able to. The same applies when the intermediate metal fitting 34 is crimped.

(Transport device)
Returning to FIG. 1, the transport device 3 is provided on the gantry 21. The transport device 3 is a linear actuator that moves the stage 2 in the left-right direction. That is, ball screws (not shown) are arranged along the left-right direction, and by rotating the ball screw with a motor (not shown), a movable portion (not shown) screwed with the ball screw is moved in the left-right direction. As a result, the stage 2 fixed to the movable portion is moved in the left-right direction.

When the caulking operation is performed, the transport device 3 transports the stage 2 to the left in the drawing along the longitudinal direction (horizontal direction) of the hose 31 starting from the start position. The transport device 3 roughly moves the stage 2 at high speed so that the crimped portion of the metal fitting 32 is located near the crimped position described later, and then the sensor described later detects the dog described later (the crimped portion is crimped). Move the stage 2 finely at low speed until it is located). The transport device 3 is provided with a start button (not shown), and when the start button is pressed, the transport device 3 starts moving the stage 2.

(Caulking device)
The caulking device 4 is arranged substantially in the center of the gantry 21. The caulking device 4 fixes the metal fitting 32 to the hose 31 by caulking the crimped portion of the metal fitting 32 (including the intermediate metal fitting 34) at the caulking position described later.

The caulking device 4 includes a plurality of claw members (not shown) arranged on the same circumference along the circumferential direction. Each claw member advances and retreats in the radial direction with respect to the caulking position which is the center of the circle. The caulking position is located on the transport path of the hose 31. When the crimped portion of the metal fitting 32 is transported to the crimped position by moving the stage 2, the stage 2 is temporarily stopped, and each claw member advances toward the crimped position, so that the crimped portion of the metal fitting 32 is moved. Be crimped.

(Dog)
Further, the hose fastening device 1 has a plurality of dogs (detection pieces) 5 as shown in FIGS. 2 and 3. The dog 5 is detected by a sensor described later. Further, the dog 5 has a movable side dog (movable side detection piece) 5a, a fixed side dog (fixed side detection piece) 5b, and positioning dogs 5c and 5d. The movable dog 5a is provided on the movable stage 13. The fixed side dog 5b is provided on the substrate 11. The positioning dogs 5c and 5d are provided on the fixed stage 12. The fixed side dog 5b may be provided on the fixed stage 12. Further, the positioning dogs 5c and 5d may be provided on the substrate 11.

The dog 5 is provided on the stage 2 for each metal fitting 32. That is, the movable side dog 5a and the fixed side dog 5b are provided for the metal fittings 32 attached to both ends of the hose 31, respectively. A positioning dog 5d located on the right side of the crimped portion C2 on the left side of the intermediate metal fitting 34 is provided. A positioning dog 5c located on the left side of the crimped portion C3 on the right side of the intermediate metal fitting 34 is provided.

As shown in FIG. 3, a slit is formed in the center of the two movable side dogs 5a and the two positioning dogs 5c and 5d. The dogs 5a, 5c, 5d in which the slits are formed are used for positioning the stage 2. In this embodiment, the width of the slit is 1 mm. On the other hand, the two fixed side dogs 5b have a protruding piece in the center thereof. The fixed side dog 5b is used to inspect the length of the hose 31. In this embodiment, the width of the protruding piece is 5 mm. The dogs 5a, 5c, and 5d used for positioning the stage 2 have protruding pieces, and a slit is formed in the fixed side dog 5b used for inspecting the length of the hose 31. May be good.

(Sensor)
Further, the hose fastening device 1 has a sensor 6 as shown in FIG. 4, which is an enlarged view of the main part A in FIG. The sensor 6 detects the dog 5 when the crimped portion of the metal fitting 32 is located at the crimped position B, and is a light emitting unit (not shown) and a light receiving unit (not shown) arranged at intervals in the vertical direction. Not shown) and. When the light emitted from the light emitting unit is incident on the light receiving unit, the sensor 6 is turned on. On the other hand, if the light emitted from the light emitting unit does not enter the light receiving unit, the sensor 6 is turned off. The sensor 6 may be turned off when the light emitted from the light emitting unit is incident on the light receiving unit, and the sensor 6 may be turned on when the light emitted from the light emitting unit is not incident on the light receiving unit.

In the present embodiment, the sensor 6 has a first sensor 6a provided on the downstream side in the transport direction of the stage 2 and a second sensor 6b provided on the upstream side in the transport direction of the stage 2. However, the number of sensors 6 is not limited to this. The first sensor 6a is arranged on the left side of the caulking position B, and the second sensor 6b is arranged on the right side of the caulking position B. In the present embodiment, the distance between the first sensor 6a and the second sensor 6b is 100 mm.

(Float detection sensor)
Further, as shown in FIG. 4, the hose fastening device 1 has a float detection sensor 7. The float detection sensor 7 can detect the float of the metal fitting 32 (including the intermediate metal fitting 34) at the caulking position B. If the metal fitting 32 is lifted from the stage 2, caulking cannot be performed correctly. Therefore, before caulking, the floating detection sensor 7 inspects the presence or absence of floating of the metal fitting 32.

The float detection sensor 7 is arranged on the left side of the caulking position B and above the caulking position B. The float detection sensor 7 has a light emitting unit (not shown) and a light receiving unit (not shown) adjacent thereto. When the stage 2 is temporarily stopped, the laser beam emitted from the light emitting portion toward the caulking position is reflected by the metal fitting 32 at the caulking position B and incident on the light receiving portion. If the distance of the laser beam emitted from the light emitting portion and incident on the light receiving portion is shorter than a predetermined length, the metal fitting 32 is raised from the recess 12a of the fixed stage 12 and the recess 13a of the movable stage 13.

(controller)
Further, the hose fastening device 1 has a controller 8 as shown in FIG. The controller 8 is electrically connected to the transport device 3, the caulking device 4, the sensor 6, and the float detection sensor 7.

When the sensor 6 detects the dog 5, the controller (transfer control device) 8 controls the transfer device 3 to temporarily stop the stage 2.

This will be specifically described with reference to FIGS. 5 to 8 which are top views showing the positional relationship between the stage 2 and the sensor 6. 5 and 8 show the first sensor 6a and the second sensor 6b. When crimping the metal fitting 32 at the left end of the hose 31, as shown in FIG. 5, the movable side dog 5a on the left side of the stage 2 is detected by the first sensor 6a. When the light from the light emitting unit passes through the slit of the movable dog 5a, the first sensor 6a is turned on. When the first sensor 6a is turned on, the controller 8 suspends the stage 2. As a result, the crimped portion C1 of the metal fitting 32 at the left end of the hose 31 is positioned at the crimped position B (see FIG. 4). In the present embodiment, the width of the slit is 1 mm, and the crimped portion C1 of the metal fitting 32 is positioned at the crimped position B with a deviation amount in the range of ± 0.5 mm.

Next, when crimping the crimped portion C2 on the left side of the intermediate metal fitting 34, as shown in FIG. 6, the positioning dog 5d on the right side of the crimped portion C2 is detected by the second sensor 6b. When the light from the light emitting unit passes through the slit of the positioning dog 5d, the second sensor 6b is turned on. When the second sensor 6b is turned on, the controller 8 suspends the stage 2. As a result, the crimped portion C2 on the left side of the intermediate metal fitting 34 is positioned at the crimped position B. In the present embodiment, the width of the slit is 1 mm, and the crimped portion C2 on the left side of the intermediate metal fitting 34 is positioned at the crimped position B with a deviation amount in the range of ± 0.5 mm.

Next, when crimping the crimped portion C3 on the right side of the intermediate metal fitting 34, as shown in FIG. 7, the positioning dog 5c on the left side of the crimped portion C3 is detected by the first sensor 6a. When the light from the light emitting unit passes through the slit of the positioning dog 5c, the first sensor 6a is turned on. When the first sensor 6a is turned on, the controller 8 suspends the stage 2. As a result, the crimped portion C3 on the right side of the intermediate metal fitting 34 is positioned at the crimped position B. In the present embodiment, the width of the slit is 1 mm, and the crimped portion C3 on the right side of the intermediate metal fitting 34 is positioned at the crimped position B with a deviation amount in the range of ± 0.5 mm.

Next, when crimping the metal fitting 32 at the right end of the hose 31, as shown in FIG. 8, the movable side dog 5a on the right side of the stage 2 is detected by the second sensor 6b. When the light from the light emitting unit passes through the slit of the movable dog 5a, the second sensor 6b is turned on. When the second sensor 6b is turned on, the controller 8 suspends the stage 2. As a result, the crimped portion C4 of the metal fitting 32 at the right end of the hose 31 is positioned at the crimped position B. In the present embodiment, the width of the slit is 1 mm, and the crimped portion C4 of the metal fitting 32 is positioned at the crimped position B with a deviation amount in the range of ± 0.5 mm.

The controller 8 controls the crimping device 4 every time the crimping portions C1 to C4 of the metal fitting 32 (including the intermediate metal fitting 34) are positioned at the caulking position B to crimp the crimping portion of the metal fitting 32. A plurality of metal fittings 32 are fixed to the hose 31 in order by one caulking device 4.

In this way, by suspending the stage 2 each time the sensor 6 detects the dog 5, the caulking points C1 to C4 of the plurality of metal fittings 32 can be sequentially positioned at the caulking position B. Then, each time the stage 2 is temporarily stopped, the plurality of metal fittings 32 can be fixed to the hose 31 in order by crimping the caulking points C1 to C4 of the metal fitting 32 at the caulking position B. As a result, the hose 31 to which the plurality of metal fittings 32 are attached can be moved in one direction, and the plurality of metal fittings 32 can be sequentially crimped to the hose 31 by one caulking device 4.

The four caulking points may be performed under the same conditions or under different conditions. That is, the caulking load, caulking speed, and the like may be different.

Further, when the controller (caulking control device) 8 inspects the length of the hose 31 when crimping the metal fittings 32 at both the left and right ends of the hose 31, if it is determined that the length of the hose 31 is abnormal, the controller (caulking control device) 8 inspects the length of the hose 31. By controlling the caulking device 4, the caulking of the metal fitting 32 is stopped. Here, the hose 31 is placed on the stage 2 so that the center position of the intermediate metal fitting 34 is the origin position. Therefore, when crimping the metal fitting 32 at the left end of the hose 31, the length from the origin position to the left end of the hose 31 is inspected, and when crimping the metal fitting 32 at the right end of the hose 31, the right end of the hose 31 is inspected. The length up to is inspected.

Here, when the length of the hose 31 is normal, the movable stage is such that the distance between the movable side dog 5a and the fixed side dog 5b is the same as the distance between the first sensor 6a and the second sensor 6b. The position of 13 is adjusted. Therefore, when the length of the hose 31 is normal, when one of the first sensor 6a and the second sensor 6b detects the movable side dog 5a, the other detects the fixed side dog 5b. However, when the length of the hose 31 is longer or shorter than the normal value, the position of the movable stage 13 deviates from the position when the length of the hose 31 is normal (normal position) in the longitudinal direction of the hose 31. As a result, if the length of the hose 31 is longer than the normal value, the distance between the movable side dog 5a and the fixed side dog 5b becomes longer than the distance between the first sensor 6a and the second sensor 6b, and the hose 31 If the length is shorter than the normal value, the distance between the movable side dog 5a and the fixed side dog 5b becomes shorter than the distance between the first sensor 6a and the second sensor 6b. Therefore, when the length of the hose 31 is not normal, even if one of the first sensor 6a and the second sensor 6b detects the movable side dog 5a, the other does not detect the fixed side dog 5b.

As shown in FIG. 5, when the first sensor 6a detects the movable side dog 5a and turns on when crimping the metal fitting 32 at the left end of the hose 31, the controller 8 causes the second sensor 6b to move the fixed side dog 5b. Is determined whether or not is detected. When the second sensor 6b is turned off (the second sensor 6b detects the fixed side dog 5b) by blocking the light emitted from the light emitting portion by the projecting piece, the movable side dog 5a and the fixed side dog 5b become The distance is the same as the distance between the first sensor 6a and the second sensor 6b, and the controller 8 determines that the length from the origin position to the left end of the hose 31 is normal. In the present embodiment, if the width of the protruding piece is 5 mm and the length from the origin position to the left end of the hose 31 is in the range of ± 2.5 mm with respect to the normal value, it is determined to be normal. To.

On the other hand, when the light emitted from the light emitting portion is incident on the light receiving portion and the second sensor 6b is turned on (the second sensor 6b does not detect the fixed side dog 5b), the movable side dog 5a and the fixed side dog 5b The distance between the first sensor 6a and the second sensor 6b is different from the distance between the first sensor 6a and the second sensor 6b, and the controller 8 determines that the length from the origin position to the left end of the hose is abnormal and outputs an error signal. ..

Further, as shown in FIG. 8, when the second sensor 6b detects the movable side dog 5a and turns ON when crimping the metal fitting 32 at the right end of the hose 31, the controller 8 causes the first sensor 6a to be fixed. It is determined whether or not the dog 5b is detected. When the light emitted from the light emitting unit is blocked by the projecting piece and the first sensor 6a is turned off (the first sensor 6a detects the fixed side dog 5b), the movable side dog 5a and the fixed side dog 5b become The distance is the same as the distance between the first sensor 6a and the second sensor 6b, and the controller 8 determines that the length from the origin position to the right end of the hose is normal. In the present embodiment, if the width of the protruding piece is 5 mm and the length from the origin position to the right end of the hose 31 is in the range of ± 2.5 mm with respect to the normal value, it is determined to be normal. To.

On the other hand, when the light emitted from the light emitting portion is incident on the light receiving portion and the first sensor 6a is turned on (the first sensor 6a does not detect the fixed side dog 5b), the movable side dog 5a and the fixed side dog 5b The distance between the first sensor 6a and the second sensor 6b is different from the distance between the first sensor 6a and the second sensor 6b, and the controller 8 determines that the length from the origin position to the right end of the hose is abnormal and outputs an error signal. ..

The error signal is input to the caulking device 4. When the caulking device 4 receives the error signal, the caulking device 4 stops caulking the metal fitting 32. Further, the error signal is input to the transport device 3. When the transport device 3 receives the error signal, the transport device 3 stops the movement of the temporarily stopped stage 2. Further, the error signal is input to a speaker (not shown), and the speaker outputs an abnormality alarm. Further, the error signal is input to a display (not shown), and the display displays an image for notifying the operator of the abnormality.

In this way, when the length of the hose is abnormal, by stopping the caulking by the caulking device 4, it is possible to prevent the metal fitting 32 from being crimped to the hose 31 having a poor length.

The transport device 3 is provided with a release button (not shown) for canceling an error. When the release button is pressed, the controller 8 stops the output of the error signal. Further, the transport device 3 is provided with a return button (not shown) for returning the stage 2 to the start position. When the return button is pressed, the controller 8 controls the transport device 3 to move the stage 2 to the start position. When an error occurs, the operator presses the release button to release the error, and then presses the return button to return the stage 2 to the start position.

In the present embodiment, the movable side dog 5a is provided with a slit so that the first sensor 6a and the second sensor 6b are turned on when the movable side dog 5a is detected. Further, by providing a protruding piece on the fixed side dog 5b, the first sensor 6a and the second sensor 6b are turned off when the fixed side dog 5b is detected. Therefore, when the first sensor 6a detects the movable dog 5a arranged on the downstream side in the transport direction of the stage 2 and turns it on, the second sensor detects the fixed dog 5b adjacent to the movable dog 5a. 6b is turned off. On the other hand, when the second sensor 6b detects the movable dog 5a arranged on the upstream side in the transport direction of the stage 2 and turns it on, the first sensor detects the fixed dog 5b adjacent to the movable dog 5a. 6a is turned off. That is, when the movable dog 5a and the fixed dog 5b arranged on the downstream side in the transport direction of the stage 2 are detected, and the movable dog 5a and the fixed dog 5b arranged on the upstream side in the transport direction of the stage 2 are detected. The ON and OFF of the first sensor 6a and the second sensor 6b are reversed when the first sensor 6a and the second sensor 6b are detected.

In this way, during a series of operations in which one hose 31 is crimped a plurality of times, the first sensor 6a and the second sensor 6b are switched between ON and OFF, respectively. It is possible to detect an abnormality of the sensor 6 at an early stage, such as not switching between ON and OFF due to a failure.

In the case where the movable dog 5a has a protruding piece and a slit is formed in the fixed dog 5b, the first sensor 6a and the second sensor 6b are turned off when the movable dog 5a is detected. , It turns ON when the fixed side dog 5b is detected. Even in such a case, the first sensor 6a and the second sensor 6b are switched between ON and OFF, respectively, during a series of operations in which one hose 31 is crimped a plurality of times. , The abnormality of the sensor 6 can be detected at an early stage.

Further, the controller (caulking stop control device) 8 controls the caulking device 4 when the floating detection sensor 7 detects the floating of the metal fitting 32 (including the intermediate metal fitting 34) when the stage 2 is temporarily stopped. As a result, the caulking of the metal fitting 32 is stopped. If the distance of the laser beam emitted from the light emitting portion of the floating detection sensor 7 toward the caulking position B, reflected by the metal fitting 32 and incident on the light receiving portion is a predetermined length, the controller 8 lifts the metal fitting 32. Judge that it is not. On the other hand, when the distance of the laser beam is shorter than the predetermined length, the controller 8 determines that the metal fitting 32 is raised and outputs an error signal.

The error signal is input to the caulking device 4. When the caulking device 4 receives the error signal, the caulking device 4 stops caulking the metal fitting 32. Further, the error signal is input to the transport device 3. When the transport device 3 receives the error signal, the transport device 3 stops the movement of the temporarily stopped stage 2. Further, the error signal is input to a speaker (not shown), and the speaker outputs an abnormality alarm. Further, the error signal is input to a display (not shown), and the display displays an image for notifying the operator of the abnormality. When an error occurs, the operator presses the release button to release the error, and then presses the return button to return the stage 2 to the start position.

In this way, when the float detection sensor 7 detects the float of the metal fitting 32, the caulking by the caulking device 4 is stopped. If the metal fitting 32 is raised, caulking cannot be performed normally. Therefore, when the metal fitting 32 is lifted, it is possible to prevent the occurrence of caulking failure by stopping the caulking by the caulking device 4.

(Operation of hose fastening device)
Next, the operation of the hose fastening device 1 will be described with reference to the flowcharts shown in FIGS. 9 and 10. The operation of the hose fastening device 1 is controlled by the controller 8.

First, as shown in FIG. 9, the controller 8 determines whether or not the start button has been pressed (step S1). When the controller 8 determines that the start button is not pressed (step S1: NO), the controller 8 repeats step S1. The operator presses the start button after placing the hose 31 to which the plurality of metal fittings 32 are attached on the stage 2 located at the start position.

Here, the spring 14 urges the movable stage 13 in the direction in which the metal fitting 32 is attached to the hose 31. As a result, the metal fitting 32 can be maintained in a state of being attached to the hose 31. Therefore, the misalignment (insufficient insertion) between the metal fitting 32 and the hose 31 can be suppressed.

When the controller 8 determines that the start button has been pressed (step S1: YES), the controller 8 controls the transport device 3 to move the stage 2 in one direction (left direction in FIG. 1) (step S2). The transport device 3 roughly moves the stage 2 at high speed so that the crimped portion C1 of the metal fitting 32 on the left end side of the stage 2 is located near the crimped position B, and then the first sensor 6a moves the movable side dog. The stage 2 is finely moved at a low speed until 5a is detected.

Next, the controller 8 determines whether or not the first sensor 6a has detected the movable dog 5a on the left end side of the stage 2 (step S3). When the controller 8 determines that the movable side dog 5a is not detected by the first sensor 6a (step S3: NO), the controller 8 returns to step S2. As a result, the stage 2 is further moved. On the other hand, when the controller 8 determines that the movable side dog 5a is detected by the first sensor 6a (step S3: YES), the controller 8 controls the transport device 3 to suspend the stage 2 (step S4).

Next, the controller 8 determines whether or not the second sensor 6b has detected the fixed side dog 5b on the left side of the stage 2 (step S5). When the controller 8 determines that the second sensor 6b has not detected the fixed side dog 5b (step S5: NO), the controller 8 outputs an error signal (step S6). That is, since the length from the origin position (center position of the intermediate metal fitting 34) to the left end of the hose 31 is abnormal, the caulking device 4 is controlled to stop the caulking of the metal fitting 32 and control the transport device 3. Then, the movement of stage 2 is stopped. In addition, the speaker or display notifies the operator that the length of the hose 31 is abnormal.

In this way, when the length of the hose 31 is abnormal, by stopping the caulking by the caulking device 4, it is possible to prevent the metal fitting 32 from being crimped to the hose 31 having a poor length.

After step S6, the controller 8 determines whether or not the release button has been pressed (step S7). When the controller 8 determines that the release button has not been pressed (step S7: NO), the controller 8 repeats step S7. On the other hand, when the controller 8 determines that the release button has been pressed (step S7: YES), the controller 8 stops the output of the error signal (step S8), and determines whether or not the return button has been pressed (step S9). ). When the controller 8 determines that the return button has not been pressed (step S9: NO), the controller 8 repeats step S9. On the other hand, when the controller 8 determines that the return button has been pressed (step S9: YES), the controller 8 conveys the stage 2 in the opposite direction (rightward direction) and moves the stage 2 to the start position (step S10). .. Then, the flow ends.

In step S5, if the controller 8 determines that the second sensor 6b has detected the fixed side dog 5b (step S5: YES), then whether or not the float detection sensor 7 has detected the float of the metal fitting. Is determined (step S11). When the controller 8 determines that the float detection sensor 7 has detected the float of the metal fitting (step S11: YES), the controller 8 proceeds to step S6. That is, since the metal fitting 32 is raised from the recess 13a of the movable stage 13, the caulking device 4 is controlled to stop the caulking of the metal fitting 32, and the transport device 3 is controlled to stop the movement of the stage 2. In addition, a speaker or a display notifies the operator that the metal fitting 32 is lifted from the stage 2.

In this way, when the metal fitting 32 is lifted, by stopping the caulking by the caulking device 4, it is possible to prevent the occurrence of caulking failure.

On the other hand, when the controller 8 determines that the floating detection sensor 7 has not detected the floating of the metal fitting (step S11: NO), the controller 8 controls the crimping device 4 to crimp the crimped portion C1 of the metal fitting 32 to the hose. It is fixed to 31 (step S12).

Next, the controller 8 controls the transport device 3 to move the stage 2 in one direction (step S13). The transport device 3 roughly moves the stage 2 at high speed so that the crimped portion C2 on the left side of the intermediate metal fitting 34 is located near the crimped position B, and then the second sensor 6b detects the positioning dog 5d. The stage 2 is moved finely at a low speed until the operation is performed.

Next, the controller 8 determines whether or not the second sensor 6b has detected the positioning dog 5d (step S14). When the controller 8 determines that the positioning dog 5d has not been detected by the second sensor 6b (step S14: NO), the controller 8 returns to step S13. As a result, the stage 2 is further moved. On the other hand, when the controller 8 determines that the positioning dog 5d is detected by the second sensor 6b (step S14: YES), the controller 8 controls the transport device 3 to suspend the stage 2 (step S15).

Next, the controller 8 determines whether or not the float detection sensor 7 has detected the float of the intermediate metal fitting 34 (step S16). When the controller 8 determines that the float detection sensor 7 has detected the float of the intermediate metal fitting 34 (step S16: YES), the controller 8 proceeds to step S6. That is, since the intermediate metal fitting 34 is raised from the recess 12a of the fixed stage 12, the caulking device 4 is controlled to stop the caulking of the intermediate metal fitting 34, and the transport device 3 is controlled to stop the movement of the stage 2. Let me. In addition, a speaker or a display notifies the operator that the intermediate metal fitting 34 is lifted from the stage 2.

On the other hand, when the controller 8 determines that the floating detection sensor 7 has not detected the floating of the intermediate metal fitting 34 (step S16: NO), the controller 8 controls the caulking device 4 to perform the caulking portion on the left side of the intermediate metal fitting 34. C2 is crimped and fixed to the hose 31 (step S17).

Moving on to FIG. 10, the controller 8 then controls the transfer device 3 to move the stage 2 in one direction (step S18). The transport device 3 roughly moves the stage 2 at high speed so that the crimped portion C3 on the right side of the intermediate metal fitting 34 is located near the crimped position B, and then the first sensor 6a detects the positioning dog 5c. The stage 2 is moved finely at a low speed until the operation is performed.

Next, the controller 8 determines whether or not the first sensor 6a has detected the positioning dog 5c (step S19). When the controller 8 determines that the positioning dog 5c has not been detected by the first sensor 6a (step S19: NO), the controller 8 returns to step S18. As a result, the stage 2 is further moved. On the other hand, when the controller 8 determines that the positioning dog 5c is detected by the first sensor 6a (step S19: YES), the controller 8 controls the transport device 3 to suspend the stage 2 (step S20).

Next, the controller 8 determines whether or not the float detection sensor 7 has detected the float of the intermediate metal fitting 34 (step S21). When the controller 8 determines that the float detection sensor 7 has detected the float of the intermediate metal fitting 34 (step S21: YES), the controller 8 proceeds to step S6. That is, since the intermediate metal fitting 34 is raised from the recess 12a of the fixed stage 12, the caulking device 4 is controlled to stop the caulking of the intermediate metal fitting 34, and the transport device 3 is controlled to stop the movement of the stage 2. Let me. In addition, a speaker or a display notifies the operator that the intermediate metal fitting 34 is lifted from the stage 2.

On the other hand, when the controller 8 determines that the floating detection sensor 7 has not detected the floating of the intermediate metal fitting 34 (step S21: NO), the controller 8 controls the caulking device 4 to perform the caulking portion on the right side of the intermediate metal fitting 34. C3 is crimped and fixed to the hose 31 (step S22).

Next, the controller 8 controls the transport device 3 to move the stage 2 in one direction (step S23). The transport device 3 roughly moves the stage 2 at high speed so that the crimped portion C4 of the metal fitting 32 on the right end side of the stage 2 is located near the crimped position B, and then the second sensor 6b moves the movable side dog. The stage 2 is finely moved at a low speed until 5a is detected.

Next, the controller 8 determines whether or not the second sensor 6b has detected the movable dog 5a on the right end side of the stage 2 (step S24). When the controller 8 determines that the second sensor 6b has not detected the movable dog 5a (step S24: NO), the controller 8 returns to step S23. As a result, the stage 2 is further moved. On the other hand, when the controller 8 determines that the movable side dog 5a is detected by the second sensor 6b (step S24: YES), the controller 8 controls the transport device 3 to suspend the stage 2 (step S25).

Next, the controller 8 determines whether or not the first sensor 6a has detected the fixed side dog 5b on the right side of the stage 2 (step S26). When the controller 8 determines that the fixed side dog 5b is not detected by the first sensor 6a (step S26: NO), the controller 8 proceeds to step S6. That is, since the length from the origin position (center position of the intermediate metal fitting 34) to the right end of the hose 31 is abnormal, the caulking device 4 is controlled to stop the caulking of the metal fitting 32 and control the transport device 3. Then, the movement of stage 2 is stopped. In addition, the speaker or display notifies the operator that the length of the hose 31 is abnormal.

On the other hand, when the controller 8 determines that the first sensor 6a has detected the fixed side dog 5b (step S26: YES), the controller 8 subsequently determines whether or not the float detection sensor 7 has detected the floating of the metal fitting. (Step S27). When the controller 8 determines that the float detection sensor 7 has detected the float of the metal fitting (step S27: YES), the controller 8 proceeds to step S6. That is, since the metal fitting 32 is raised from the recess 13a of the movable stage 13, the caulking device 4 is controlled to stop the caulking of the metal fitting 32, and the transport device 3 is controlled to stop the movement of the stage 2. In addition, a speaker or a display notifies the operator that the metal fitting 32 is lifted from the stage 2.

On the other hand, when the controller 8 determines that the floating detection sensor 7 has not detected the floating of the metal fitting (step S27: NO), the controller 8 controls the crimping device 4 to crimp the crimped portion C4 of the metal fitting 32 to the hose. It is fixed to 31 (step S28).

As described above, by suspending the stage 2 each time the sensor 6 detects the dog 5, the caulking points C1 to C4 of the plurality of metal fittings 32 can be sequentially positioned at the caulking position B. Then, each time the stage 2 is temporarily stopped, the plurality of metal fittings 32 can be fixed to the hose 31 in order by crimping the caulking points C1 to C4 of the metal fitting 32 at the caulking position B. As a result, the hose 31 to which the plurality of metal fittings 32 are attached can be moved in one direction, and the plurality of metal fittings 32 can be sequentially crimped to the hose 31 by one caulking device 4.

Further, during a series of operations in which one hose 31 is crimped a plurality of times, the first sensor 6a and the second sensor 6b are switched between ON and OFF, respectively, due to a failure. It is possible to detect an abnormality of the sensor 6 at an early stage, such as not switching between ON and OFF.

After that, the controller 8 conveys the stage 2 in the opposite direction (rightward direction) and moves the stage 2 to the start position (step S29). Then, the flow ends. The hose 31 after caulking will be removed from the stage 2 returned to the starting position.

After step S28, the stage 2 is further conveyed in one direction and temporarily stopped, and after the hose 31 is removed from the stage 2, the stage 2 is conveyed in the opposite direction (right direction) to the start position. It may be configured to be restored.

(effect)
As described above, according to the hose fastening device 1 according to the present embodiment, the stage 2 on which the hose 31 on which the plurality of metal fittings 32 are mounted is placed is conveyed in one direction, and each of the plurality of metal fittings 32 is conveyed. Every time the sensor 6 detects the provided dog 5, the stage 2 is temporarily stopped and caulking is performed. By suspending the stage 2 each time the sensor 6 detects the dog 5, the caulking points C1 to C4 of the plurality of metal fittings 32 can be sequentially positioned at the caulking position B. Then, each time the stage 2 is temporarily stopped, the plurality of metal fittings 32 can be fixed to the hose 31 in order by crimping the caulking points C1 to C4 of the metal fitting 32 at the caulking position B. As a result, the hose 31 to which the plurality of metal fittings 32 are attached can be moved in one direction, and the plurality of metal fittings 32 can be sequentially crimped to the hose 31 by one caulking device 4.

Further, by urging the movable stage 13 with the spring 14 in the direction in which the metal fitting 32 is attached to the hose 31, the state in which the metal fitting 32 is attached to the hose 31 can be maintained. Therefore, the misalignment (insufficient insertion) between the metal fitting 32 and the hose 31 can be suppressed.

Further, the movable stage 13 can move in the direction in which the metal fitting 32 is attached to the hose 31 by being urged by the spring 14, and the metal fitting 32 is attached to the hose 31 against the urging force of the spring 14. It can move in the direction opposite to the mounting direction. Therefore, even if there is a variation in the length of the cutting hose 33, this variation can be absorbed by the movement of the movable stage 13. Further, even if the cutting hose 33 is slightly stretched when the metal fitting 32 is crimped, the movable stage 13 absorbs the stretched allowance by moving in the direction opposite to the direction in which the metal fitting 32 is attached to the hose 31. be able to. The same applies when the intermediate metal fitting 34 is crimped.

Further, when the length of the hose 31 is normal, the movable stage 13 is provided so that the distance between the movable side dog 5a and the fixed side dog 5b is the same as the distance between the first sensor 6a and the second sensor 6b. The position of is adjusted. Therefore, when the length of the hose 31 is normal, when one of the first sensor 6a and the second sensor 6b detects the movable side dog 5a, the other detects the fixed side dog 5b. However, when the length of the hose 31 is longer or shorter than the normal value, the position of the movable stage 13 deviates from the position when the length of the hose 31 is normal (normal position) in the longitudinal direction of the hose 31. As a result, the distance between the movable side dog 5a and the fixed side dog 5b becomes longer or shorter than the distance between the first sensor 6a and the second sensor 6b. Therefore, when the length of the hose 31 is abnormal, even if one of the first sensor 6a and the second sensor 6b detects the movable side dog 5a, the other does not detect the fixed side dog 5b. In this case, by stopping the caulking by the caulking device 4, it is possible to prevent the metal fitting 32 from being crimped to the hose 31 having a poor length.

Further, the first sensor 6a and the second sensor 6b are turned on when the movable side dog 5a is detected, and turned off when the fixed side dog 5b is detected. Alternatively, the first sensor 6a and the second sensor 6b are turned off when the movable side dog 5a is detected, and turned on when the fixed side dog 5b is detected. Therefore, when the first sensor 6a detects the movable dog 5a arranged on the downstream side in the transport direction of the stage 2 and turns it on, the second sensor detects the fixed dog 5b adjacent to the movable dog 5a. 6b is turned off. On the other hand, when the second sensor 6b detects the movable dog 5a arranged on the upstream side in the transport direction of the stage 2 and turns it on, the first sensor detects the fixed dog 5b adjacent to the movable dog 5a. 6a is turned off. That is, when the movable dog 5a and the fixed dog 5b arranged on the downstream side in the transport direction of the stage 2 are detected, and the movable dog 5a and the fixed dog 5b arranged on the upstream side in the transport direction of the stage 2 are detected. The ON and OFF of the first sensor 6a and the second sensor 6b are reversed when the first sensor 6a and the second sensor 6b are detected. The same applies to the case where it is turned off when the movable side dog 5a is detected and turned on when the fixed side dog 5b is detected. In this way, during a series of operations in which one hose 31 is crimped a plurality of times, the first sensor 6a and the second sensor 6b are switched between ON and OFF, respectively. It is possible to detect an abnormality of the sensor 6 at an early stage, such as not switching between ON and OFF due to a failure.

Further, when the floating detection sensor 7 detects the floating of the metal fitting 32, the caulking by the caulking device 4 is stopped. If the metal fitting 32 is raised, caulking cannot be performed normally. Therefore, when the metal fitting 32 is lifted, it is possible to prevent the occurrence of caulking failure by stopping the caulking by the caulking device 4.

Although the embodiments of the present invention have been described above, only specific examples are illustrated, and the present invention is not particularly limited, and the specific configuration and the like can be appropriately redesigned. In addition, the actions and effects described in the embodiments of the present invention merely list the most preferable actions and effects arising from the present invention, and the actions and effects according to the present invention are described in the embodiments of the present invention. It is not limited to what has been done.

1 Hose fastening device 2 Stage 3 Conveying device 4 Caulking device 5 Dog (detection piece)
5a Movable side dog (movable side detection piece)
5b Fixed side dog (fixed side detection piece)
5c, 5d Positioning dog 6 sensor 6a 1st sensor 6b 2nd sensor 7 Float detection sensor 8 Controller (convey control device, caulking control device, caulking stop control device)
11 Substrate 12 Fixed stage 12a Recessed 13 Movable stage 13a Recessed 14 Spring (urging means)
15 Rail 16 Fixture 17 Stripper bolt 21 Stand 31 Hose 32 Metal fittings 33 Cutting hose 34 Intermediate metal fittings

Claims (5)

A hose fastening device that crimps and fixes metal fittings to the hose at each of a plurality of locations in the longitudinal direction of the hose.
A stage on which the hose to which the plurality of metal fittings are mounted is placed, and
A transport device that transports the stage in one direction along the longitudinal direction of the hose,
A plurality of detection pieces provided on the stage for each metal fitting,
A sensor that detects the detection piece when the crimped portion of the metal fitting is located at the crimped position, and
A controller that suspends the stage by controlling the transport device when the sensor detects the detection piece.
When the stage is temporarily stopped, one crimping device for fixing the metal fitting to the hose by crimping the crimping portion of the metal fitting at the crimping position.
Have a,
The controller temporarily stops the stage each time the sensor detects the detection piece while transporting the stage in one direction by the transport device, thereby crimping the plurality of the metal fittings into the one unit. A hose fastening device, characterized in that the hose is fixed to the hose in order. The stage
The substrate conveyed by the transfer device and
A fixing stage arranged at the center of the board in the longitudinal direction of the hose, fixed on the board, and supporting a part of the hose to which the metal fittings are mounted.
A movable stage that is arranged at both ends of the substrate in the longitudinal direction of the hose, is provided on the substrate so as to be movable in the longitudinal direction of the hose, and supports the metal fittings.
An urging means provided on the substrate and urging the movable stage in a direction in which the metal fitting is attached to the hose.
The hose fastening device according to claim 1, wherein the hose fastening device comprises. The detection piece is
The movable side detection piece provided on the movable stage and
With the fixed side detection piece provided on the substrate or on the fixed stage,
Have,
The sensor is
The first sensor provided on the downstream side in the transport direction of the stage and
A second sensor provided on the upstream side in the transport direction of the stage and
Have,
When the length of the hose is normal, the movable stage is such that the distance between the movable side detection piece and the fixed side detection piece is the same as the distance between the first sensor and the second sensor. The position of is adjusted,
When one of the first sensor and the second sensor detects the movable side detection piece and the other does not detect the fixed side detection piece when the stage is temporarily stopped, the caulking device is controlled. The hose fastening device according to claim 2, further comprising a caulking control device for stopping caulking of the metal fitting. The first sensor and the second sensor are turned on when the movable side detection piece is detected and turned off when the fixed side detection piece is detected, or when the movable side detection piece is detected. The hose fastening device according to claim 3, wherein the hose is turned off when the fixed side detection piece is detected. A float detection sensor capable of detecting the float of the metal fitting at the crimped position when the stage is temporarily stopped.
When the floating detection sensor detects the floating of the metal fitting, the caulking stop control device for stopping the caulking of the metal fitting by controlling the caulking device,
The hose fastening device according to any one of claims 1 to 4, further comprising.

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